Synthesis and Characterization of Octa- and Hexanuclear

Inorg. Chem. 2006, 45, 5898−5910

Synthesis and Characterization of Octa- and Hexanuclear Polyoxomolybdate Wheels: Role of the Inorganic Template and of the Counterion Anne Dolbecq,*,† Laurent Lisnard,† Pierre Mialane,† Je´roˆme Marrot,† Marc Be´nard,‡ Marie-Madeleine Rohmer,‡ and Francis Se´cheresse† Institut LaVoisier de Versailles, UMR 8180, UniVersite´ de Versailles Saint-Quentin en YVelines, 45 AVenue des Etats-Unis, 78035 Versailles Cedex, France, and Laboratoire de Chimie Quantique, Institut de Chimie, UMR 7177, CNRS/UniVersite´ Louis Pasteur, 4 rue Blaise Pascal, 67037 Strasbourg Cedex, France Received March 10, 2006

Eight new compounds based on [O3PCH2PO3]4- ligands and {MoV2O4} dimeric units have been synthesized and structurally characterized. Octanuclear wheels encapsulating various guests have been isolated with different counterions. With NH4+, a single wheel was obtained, as expected, with the planar CO32- guest, (NH4)12[(MoV2O4)4(O3PCH2PO3)4(CO3)2]‚24H2O (1a), while with the pyramidal SO32- guest, only the syn isomer (NH4)12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚26H2O (2a) was characterized. The corresponding anti isomer was obtained with Na+ as counterions, Na12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚39H2O (2b), and with mixed Na+ and NH4+ counterions, Na+(NH4)11[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚13H2O (2d). With [O3PCH2PO3]4- extra ligands, the octanuclear wheel Li12(NH4)2[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚31H2O (4a) was isolated with Li+ and NH4+ counterions and Li14[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚34H2O (4c) as a pure Li+ salt. A new rectangular anion, formed by connecting two MoV dimers and two MoVI octahedra via methylenediphosphonato ligands with NH4+ as counterions, (NH4)10[(MoV2O4)2(MoVIO3)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚15H2O (3a), and Li9(NH4)2Cl[(MoV2O4)2(MoVIO3)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚ 22H2O (3d) as a mixed NH4+ and Li+ salt have also been synthesized. The structural characterization of the compounds, combined with a study of their behavior in solution, investigated by 31P NMR, has allowed a discussion on the influence of the counterions on the structure of the anions and their stability. Density functional theory calculations carried out on both isomers of the [(MoV2O4)4(O3PCH2PO3)4(SO3)2]12- anion (2), either assumed isolated or embedded in a continuum solvent model, suggest that the anti form is favored by ∼2 kcal mol-1. Explicit insertion of two solvated counterions in the molecular cavity reverses this energy difference and reduces it to less than 1 kcal mol-1, therefore accounting for the observed structural versatility.

Introduction Poly(oxometalates) (POMs) continue to attract interest for their potential applications in the field of catalysis, medicine, and material chemistry.1 Structural types such as the Keggin and Dawson types have been studied extensively.2 These POMs are built from the connection of MoVI or WVI octahedra around a tetrahedral heteroelement. One of the * To whom correspondence should be addressed. E-mail: dolbecq@ chimie.uvsq.fr. † Universite ´ de Versailles Saint-Quentin en Yvelines. ‡ CNRS/Universite ´ Louis Pasteur. (1) Special issue on poly(oxometalates): Chem. ReV. 1998, 98, 1-387. (2) Pope, M. T. Heteropoly and isolopoly oxometalates; Spring-Verlag: Berlin, 1983.

5898 Inorganic Chemistry, Vol. 45, No. 15, 2006

strategies for the synthesis of new POM frameworks involves the reduction of poly(oxomolybdates) to give either mixedvalence compounds or fully reduced poly(oxomolybdates) containing the {MoV2O4} dimeric structural unit. The reduction can be achieved at room temperature by using a reducing agent such as hydrazine. The group of Mu¨ller has extensively used this approach for the design of beautiful and complex wheel-shaped nanosized molecular systems.3 On the other hand, since the first results published by Haushalter and Mundi,4 hydrothermal conditions with metallic Mo powder as the usual reducing agent have been successful for the (3) For example, see: Mu¨ller, A.; Roy, S. Coord. Chem. ReV. 2003, 153. (4) Haushalter, R.; Mundi, L. Chem. Mater. 1992, 4, 31.

10.1021/ic060410+ CCC: $33.50

© 2006 American Chemical Society Published on Web 06/23/2006

Octa- and Hexanuclear Polyoxomolybdate Wheels

synthesis of a great number of molecular, one-, two-, or threedimensional reduced compounds.5 The most often encountered structural unit in the family of fully reduced phosphateand organophosphonatemolybdenum(V) compounds isolated by hydrothermal techniques is the hexanuclear anion built from the connection of three {MoV2O4} dimeric fragments around a central phosphate or organophosphonate ligand, with three peripheral phosphate6 or organophosphonate ligands.7 Syntheses under standard bench conditions afford a large structural diversity of almost exclusively molecular MoV compounds. Working in nonaqueous solvents, Modec et al. have synthesized numerous MoV compounds, with organic ligands coordinated to the Mo ions.8 Kamenar et al. have functionalized the dimeric fragment by sophisticated organic ligands.9 Kabanos et al. have prepared polyoxomolybdenum(V) complexes with carbonate10 or sulfite ligands.11 In all these complexes, only one type of organic or inorganic ligand is present. Besides, Kortz and Pope have shown that the reaction of [O3PXPO3]4- (X ) O, CH2) ligands with MoVI ions could afford a diversity of polyoxomolybdates.12 We have thus recently initiated a study on the acid-base condensation of the dinuclear [MoV2O4(H2O)6]2+ oxocation with [O3PCH2PO3]4- in the presence of a templating exogeneous ligand (acetate, formiate, or carbonate) and described the synthesis of four cyclic MoV complexes in an aqueous medium.13 Additionally, a tetranuclear MoV complex with methylenediphosphonate ligands, [MoV4O10(O3PCH2PO3)2]4-, had been synthesized in CH3CN by Chang and Zubieta.14 All five complexes contain a {(MoV2O4)(O3PCH2PO3)} structural unit, but the connecting modes are completely different. In the cyclic compounds,13 the MoV octahedra are edge-sharing and the organophos(5) For recent examples, see: (a) Khan, M. I.; Chen, Q.; Salta, J.; O’Connor, C.; Zubieta, J. Inorg. Chem. 1996, 35, 1880. (b) Dumas, E.; Sassoye, C.; Smith, K. D.; Sevov, S. C. Inorg. Chem. 2002, 41, 4029. (c) du Peloux, C.; Dolbecq, A.; Mialane, P.; Marrot, J.; Rivie`re, E.; Se´cheresse, F. Angew. Chem., Int. Ed. 2001, 40, 2455. (d) Calin, N.; Sevov, S. C. Inorg. Chem. 2003, 42, 7304. (6) For example, see: (a) Guesdon, A.; Borel, M. M.; Leclaire, A.; Raveau, B. Chem.sEur. J. 1997, 3, 1797. (b) Xu, L.; Sun, Y.; Wang, E.; Shen, E.; Liu, Z.; Hu, C.; Xing, Y.; Lin, Y.; Jia, H. J. Solid State Chem. 1999, 146, 533. (c) du Peloux, C.; Mialane, P.; Dolbecq, A.; Marrot, J.; Rivie`re, E.; Se´cheresse, F. J. Mater. Chem. 2001, 3392. (7) (a) Cao, G.; Haushalter, R. C.; Strohmaier, K. G. Inorg. Chem. 1993, 32, 127. (b) Khan, M. I.; Chen, Q.; Zubieta, J. Inorg. Chim. Acta 1993, 206, 131. (c) Xu, L.; Sun, Y.; Wang, E.; Shen, E.; Liu, Z.; Hu, C.; Xing, Y.; Lin, Y.; Jia, H. J. Solid State Chem. 1999, 146, 533. (8) (a) Modec, B.; Brencic, J. V.; Zubieta, J. J. Chem. Soc., Dalton Trans. 2002, 1500. (b) Modec, B.; Brencic, J. V.; Burkholder, E. M.; Zubieta, J. J. Chem. Soc., Dalton Trans. 2003, 4618. (c) Modec, B.; Brencic, J. V.; Koller, J. Eur. J. Inorg. Chem. 2004, 161. (9) (a) Cindric, M.; Vrdoljak, V.; Novak, T. K.; Strukan, N.; BrbotSaranovic, A.; Novak, P.; Kamenar, B. Polyhedron 2004, 23, 1859. (b) Cindric, M.; Vrdoljak, V.; Strukan, N.; Tepes, P.; Novak, P.; BrbotSaranovic, A.; Kamenar, B. Eur. J. Inorg. Chem. 2002, 2128. (10) Manos, M. J.; Keramidas, A. D.; Woollins, J. D.; Slawin, A. M. Z.; Kabanos, T. A. J. Chem. Soc., Dalton Trans. 2001, 3419. (11) (a) Manos, M. J.; Woollins, J. D.; Slawin, A. M.; Kabanos, T. A. Angew. Chem., Int. Ed. 2002, 41, 2801. (b) Miras, H. N.; Woollins, J. D.; Slawin, A. M.; Raptis, R.; Baran, P.; Kabanos, T. A. Dalton Trans. 2003, 3668. (12) (a) Kortz, U. Inorg. Chem. 2000, 39, 625. (b) Kortz, U. Inorg. Chem. 2000, 39, 623. (c) Kortz, U.; Pope, M. T. Inorg. Chem. 1995, 34, 2160. (d) Kortz, U.; Pope, M. T. Inorg. Chem. 1994, 33, 5643. (13) du Peloux, C.; Dolbecq, A.; Mialane, P.; Marrot, J.; Se´cheresse, F. Dalton Trans. 2004, 1259. (14) Chang, Y.-D.; Zubieta, J. Inorg. Chim. Acta 1996, 245, 177.

Figure 1. Structure of the {(MoV2O4)(O3PCH2PO3)} unit (a) in the cyclic compounds synthesized in water13 and (b) in the tetranuclear complex isolated in CH3CN.14 Orange octahedra ) MoO6. Green tetrahedra ) PO3C.

phonate ligand is connected only to one edge of a MoV octahedron with Mo-Mo and P-P bonds almost perpendicular (Figure 1a), while in the tetranuclear complex,14 the MoV octahedra share one face and the ligand is connected to both MoV octahedra (Figure 1b). The complexes previously synthesized in an aqueous medium13 were all Na+ salts. We show here how the nature of the counterion in combination with the nature of the exogeneous template (carbonate, sulfite, and molybdate) strongly influences the structure of the obtained MoV complexes. X-ray diffraction studies have been performed to characterize the complexes in the solid state, and their behavior in solution has been thoroughly investigated by 31P NMR, evidencing subtle equilibrium between some species. Density functional theory (DFT) calculations are used to investigate the energy balance between the syn and anti isomers of a hexanuclear wheel and how this balance can be influenced by the nature of the counterions and by the crystal or solvent environment. Experimental Section Preparation of a 0.10 M Solution of [Mo2O4(H2O)6]2+ in 4 M HCl. A total of 2.91 g (2.35 mmol) of (NH4)6MoVI7O24‚4H2O was dissolved in 80 mL of 4 M HCl, and then 210 µL (4.29 mmol) of N2H4‚H2O was added. The solution turned progressively to red during stirring for 3 h at 60 °C. The solution was then allowed to cool to room temperature. The procedure is identical starting from Na2MoVIO4‚2H2O (4 g, 16.53 mmol) or Li2MoVIO4 (2.87 g, 16.51 mmol). Synthesis of (NH4)12[(MoV2O4)4(O3PCH2PO3)4(CO3)2]‚24H2O (1a). A saturated solution of NH4HCO3 was added dropwise until pH ) 1.5 to 12.5 mL (1.29 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of (NH4)6Mo7O24‚4H2O as described above. A total of 0.227 g (1.29 mmol) of H4P2CH2O6 was then added, and the pH was increased to 5.7 by the addition of saturated aqueous ammonium hydrogen carbonate. The solution was then left to evaporate at room temperature. Red parallelepipedic crystals were collected by filtration after 1 week. Yield: 0.33 g (41% based on Mo). FTIR (KBr pellets, cm-1): 1466(s), 1445(s,sh), 1397(s), 1176(s), 1110(sh), 1085(s), 1055(s), 1028(s), 1012(s), 952(s), 916(m,sh), 841(w), 804(m), 747(m), 576(m), 551(m,sh), 482(m). Anal. Calcd for C6H104Mo8N12O70P8 (2480.25): C, 2.91; Mo, 30.94; N, 6.78; P, 9.99. Found: C, 3.09; Mo, 31.04; N, 7.17; P, 9.63. Synthesis of (NH4)12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚26H2O (2a). A total of 1.0 g (7.46 mmol) of (NH4)2SO3‚H2O was added to 12.5 mL (1.29 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of (NH4)6Mo7O24‚4H2O as described above, and concentrated NH3 was added dropwise until pH ) 1.5. A total of 0.227 g (1.29 mmol) of H4P2CH2O6 was then added, and the pH was increased to 5.7 by the addition of concentrated NH3. After the orange precipitate that had formed was stirred until it dissolved (∼30 min), the solution was left to evaporate at room temperature. Inorganic Chemistry, Vol. 45, No. 15, 2006

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Dolbecq et al. Red parallelepipedic crystals were collected by filtration after 2 days. Yield: 0.19 g (23% based on Mo). FTIR (KBr pellets, cm-1): 1443(m), 1397(s), 1185(m), 1060(s), 1025(s), 1012(s,sh), 948(m), 902(m), 802(m), 735(w), 557(w), 516(w), 484(w). Anal. Calcd for C4H108Mo8N12O72P8S2 (2556.39): C, 1.88; Mo, 30.02; N, 6.57; P, 9.69; S, 2.51. Found: C, 1.73; Mo, 29.85; N, 6.55; P, 9.88; S, 2.77. Synthesis of (NH4)10[(MoV2O4)2(MoVIO3)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚15H2O (3a). A total of 0.114 g (0.092 mmol) of (NH4)6Mo7O24‚4H2O and 0.227 g of (1.29 mmol) of H4P2CH2O6 were added to 6.25 mL (0.64 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of (NH4)6Mo7O24‚4H2O as described above, and concentrated NH3 was added dropwise until pH ) 6.2. The solution was left to evaporate at room temperature. Red parallelepipedic crystals were collected by filtration after 2 days. Yield: 0.52 g (83% based on Mo). FTIR (KBr pellets, cm-1): 1404(s), 1194(m,sh), 1169(s), 1121(s), 1062(s), 1005(s), 952(s), 904(m), 845(m), 815(s), 742(m), 544(m), 482(m), 448(w). Anal. Calcd for C4H80Mo6N10O53P8 (1940.15): C, 2.48; Mo, 29.67; N, 7.22; P, 12.77. Found: C, 2.77; Mo, 29.45; N, 7.65; P, 12.14. Synthesis of Li12(NH4)2[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚31H2O (4a). A total of 0.39 g (0.19 mmol) of 3d was dissolved in 8 mL of 4 M LiCl, and the solution was left at room temperature to evaporate. Red crystals were mechanically separated from an orange powder after sonication. Yield: 0.06 g (15% based on Mo). FTIR (KBr pellets, cm-1): 1400(s), 1025(s,sh), 1179(s), 1156(s), 1110(s), 1070(s), 1012(s), 953(s), 919(m), 806(s), 743(w), 628(w), 544(m), 485(m). Anal. Calcd for C6H84Li12Mo8N2O83P12 (2735.20): C, 2.63; H, 3.09; Li, 3.04; Mo, 28.06; N, 1.02; P, 13.59. Found: C, 2.78; H, 2.90; Li, 3.01; Mo, 28.10; N, 1.13; P, 13.39. Synthesis of Na12[(MoV2O4)4(O3PCH2PO3)4(CO3)2]‚72H2O (1b). 1b was synthesized as previously described.13 Synthesis of Na12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚39H2O (2b). A total of 0.5 g (4 mmol) of Na2SO3 was added to 6.25 mL (0.64 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of Na2MoO4‚2H2O as described above and a saturated NaOH solution was added dropwise until pH ) 1.5. A total of 0.113 g (0.64 mmol) of H4P2CH2O6 was then added, and the pH was increased to 5.7 by the addition of a saturated NaOH solution. The solution was left to evaporate at room temperature. Red parallelepipedic crystals were collected by filtration after 2 days. Yield: 0.28 g (61% based on Mo). FTIR (KBr pellets, cm-1): 1369(w), 1184(s), 1117(m), 1066(s), 1027(s), 1008(s,sh), 953(s), 897(m), 849(w), 799(w), 744(w), 553(m), 518(m), 489(m), 407(w), 341(w), 302(w), 280(w). Anal. Calcd for C4H86Mo8Na12O85P8S2 (2850.00): C, 1.69; Mo, 26.93; Na, 9.68; P, 8.69; S, 2.25. Found: C, 1.93; Mo, 26.51; Na, 10.39; P, 8.74; S, 2.36. Improved Synthesis of Na8[(MoV2O4)3(O3PCH2PO3)3(MoVIO4)]‚ 18H2O (3b). The synthesis of 3b in a 4 M sodium acetate buffer has been previously described.13 The yield can be significantly improved by modifying the synthetic procedure. A total of 0.104 g (0.43 mmol) of Na2MoO4‚2H2O and 0.227 g (1.29 mmol) of H4P2CH2O6 were added to 12.5 mL (1.29 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of Na2MoO4‚2H2O as described above, and a saturated NaOH solution was added dropwise until pH ) 6.0. The solution was left to evaporate at room temperature. Red parallelepipedic crystals were collected by filtration after 5 days. Yield: 0.40 g (48% based on Mo). FTIR (KBr pellets, cm-1): 1190(s), 1157(s), 1117(m), 1067(s), 1026(s), 949(s), 905(w,sh), 826(w), 798(m), 754(s), 721(m,sh), 553(w), 509(m), 455(w), 393(w), 341(m), 295(w), 260(w). Anal. Calcd for C3H42Mo7Na8O52P6 (1951.68): C, 1.85; H, 2.33; Mo, 34.41; Na+, 9.42; P, 9.52. Found: C, 1.91; H, 2.16; Mo, 33.62; Na+, 9.44; P, 9.60.

5900 Inorganic Chemistry, Vol. 45, No. 15, 2006

[(MoV

Synthesis of a Solution of Li12 2O4)4(O3PCH2PO3)4(CO3)2]‚nH2O (1c). A saturated solution of Li2CO3 was added dropwise until pH ) 1.5 to 12.5 mL (1.29 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of Li2MoO4 as described above. A total of 0.227 g (1.29 mmol) of H4P2CH2O6 was then added, and the pH was increased to 5.7 by the addition of saturated aqueous lithium carbonate. The 31P NMR spectrum of the synthetic solution shows that the major product of the reaction is 1c. However, no crystals could be obtained by slow evaporation of the solution, probably because of the high solubility of 1c. Synthesis of Li8[(MoV2O4)3(O3PCH2PO3)3(MoVIO4)]‚19H2O (3c). A total of 0.074 g (0.43 mmol) of Li2MoO4 and 0.227 g (1.29 mmol) of H4P2CH2O6 were added to 12.5 mL (1.29 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of Li2MoO4 as described above, and a saturated LiOH solution was added dropwise until pH ) 6.0. The solution was left to evaporate at room temperature. Orange needle crystals were collected by filtration after 5 days. Yield: 0.42 g (53% based on Mo). FTIR (KBr pellets, cm-1): 1192(s), 1152(m), 1123(m,sh), 1077(s), 1030(s), 964(s), 922(w,sh), 812(m), 759(s), 549(s), 512(s,sh), 459(m). Anal. Calcd for C3H44Li8Mo7O53P6 (1841.31): C, 1.95; H, 2.41; Li, 3.01; Mo, 36.47; P, 10.09. Found: C, 2.15; H, 2.50; Li, 3.18; Mo, 32.95; P, 10.26. Synthesis of Li14[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚ 34H2O (4c). A saturated LiOH solution was added dropwise to 6.25 mL (0.64 mmol) of a solution of [Mo2O4(H2O)6]2+ obtained from the reduction of Li2MoO4 as described above until pH ) 1.5. A total of 0.169 g (0.96 mmol) of H4P2CH2O6 was added, and the pH was adjusted to 3.5 with a saturated LiOH solution. Red parallelepipedic crystals were collected by filtration after 5 days. Yield: 0.22 g (50% based on Mo). FTIR (KBr pellets, cm-1): 1368(w), 1184(s), 1156(s,sh), 1107(s), 1089(s,sh), 1062(s), 1027(s), 1007(s,sh), 960(s), 805(w), 778(w), 741(w), 572(m), 523(m), 486(m). Anal. Calcd for C6H82Li14Mo8O86P12 (2767.06): C, 2.60; H, 2.98; Li+, 3.51; Mo, 27.73; P, 13.43. Found: C, 2.62; H, 2.62; Li+, 3.45; Mo, 27.64; P, 13.78. Synthesis of Na(NH4)11[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚ 13H2O (2d). A total of 0.460 g of 2b was dissolved in 7.6 mL of 1 M (NH4)2SO3 adjusted to pH ) 5.7. Red parallepipedic crystals were collected after 5 days. Yield: 0.36 g (80% based on Mo). The FTIR spectrum is similar to that of 2b. Anal. Calcd for C4H78Mo8N11NaO59P8S2 (2327.14): C, 2.06; H, 3.38; Mo, 32.98; N, 6.62; Na, 0.99; P, 10.64. Found: C, 2.01; H, 3.56; Mo, 33.02; N, 6.77; Na, 1.18; P, 9.85. Synthesis of Li9(NH4)2Cl[(MoV2O4)2(MoVIO3)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚22H2O (3d). A total of 0.6 g (0.31 mmol) of 3a was dissolved in 9 mL of 4 M LiCl, and the solution was left to evaporate at room temperature. Red crystals were collected after 2 days. Yield: 0.44 g (69% based on Mo). FTIR (KBr pellets, cm-1): 1397(s), 1207(m,sh), 1178(s), 1156(s,sh), 1111(m), 1067(s), 1014(s), 951(m), 918(w), 856(w), 812(s), 741(w), 546(m), 483(m), 397(w). Anal. Calcd for C4H62ClLi9Mo6N2O60P8 (2019.87): C, 2.38; H, 3.09; Cl, 1.75; Li, 3.09; Mo, 28.50; N, 1.39; P, 12.27. Found: C, 2.25; H, 2.76; Cl, 2.00; Li, 3.00; Mo, 28.11; N, 1.47; P, 12.03. X-ray Crystallography. Intensity data collection was carried out with a Siemens SMART three-circle diffractometer for all of the structures except for 2a, for which the data were collected with a Bruker Nonius X8 APEX 2 diffractometer, each equipped with a CCD two-dimensional detector using the monochromatized wavelength λ(Mo KR) ) 0.710 73 Å. The absorption correction was based on multiple and symmetry-equivalent reflections in the data set using the SADABS program15 based on the method of Blessing.16 The structures were solved by direct methods and refined

0.0614 0.1543 0.0755 0.1902 0.0528 0.1359 0.0433 0.1039

Inorganic Chemistry, Vol. 45, No. 15, 2006

a

R1 ) ∑|Fo| - |Fc|)/(∑|Fc|. b wR2 )

x∑w(Fo2-Fc2)2/(∑w(Fo2)2).

0.0453 0.1342 0.0528 0.1564 0.0689 0.1739

0.0768 0.1983

13.7096(2) 14.2642(2) 17.4993(3) 101.401(1) 104.101(1) 108.799(1) 2996.41(8) 2 2.274 1.610 14721/817 0.0336 1.068 9.6783(2) 14.2098(2) 14.3744(2) 95.289(1) 95.533(1) 96.213(1) 1945.55(6) 1 2.221 1.608 9627/436 0.0322 1.086 11.8591(1) 12.9812(1) 16.0452(1) 101.200(1) 107.477(1) 108.067(1) 1960.72(3) 1 2.310 1.602 9767/553 0.0244 1.103 11.6173(5) 13.3978(6) 13.6621(6) 75.507(1) 72.349(1) 85.182(1) 1961.79(15) 1 2.412 1.662 5628/513 0.0293 1.073 13.422(3) 16.329(1) 18.598(2) 90 102.214(11) 90 3983.7(10) 2 2.280 1.597 5728/563 0.0288 0.948 14.439(1) 16.333(1) 16.610(1) 82.917(3) 88.179(3) 79.074(3) 3816.7(4) 2 2.225 1.626 17414/962 0.0541 1.131 16.464(8) 13.222(7) 17.357(12) 90 114.51(2) 90 3438(3) 2 2.396 1.741 4960/433 0.0714 1.027

13.4897(2) 13.7119(2) 17.9603(1) 73.936(1) 77.086(1) 64.900(1) 2869.36(6) 2 2.283 1.628 8166/703 0.0541 1.154

2051.87 triclinic P1h 2327.14 triclinic P1h 2767.04 triclinic P1h 2850.00 triclinic P1h 2735.19 monoclinic P21/n 2556.39 triclinic P1h 2480.29 monoclinic P21/c

1972.18 triclinic P1h

C7H78Mo8N11NaO59P8S2 C6H82Li14Mo8O86P12 C4H86Mo8Na12O85P8S2 C6H84Li12Mo8N2O83P12 C4H80Mo6N10O53P8 C4H108Mo8N12O72P8S2 C6H104Mo8N12O70P8

empirical formula fw, g cryst syst space group a/Å b/Å c/Å R/deg β/deg γ/deg V/Å3 Z Fcalc/g cm-3 µ/mm-1 data/param Rint GOF R [I >2σ(I)] R1a wR2b

2d 4c 2b 4a 3a 2a 1a

Table 1. Crystallographic Data for 1a-4a, 2b, 4c, 2d, and 3d

(15) Sheldrick, G. M. SADABS, program for scaling and correction of area detector data; University of Go¨ttingen: Go¨ttingen, Germany, 1997. (16) Blessing, R. Acta Crystallogr. 1995, A51, 33. (17) Sheldrick, G. M. SHELX-TL, version 5.03; Software Package for the Crystal Structure Determination; Siemens Analytical X-ray Instrument Division: Madison, WI, 1994. (18) Baerends, E. J.; Autschbach, J.; Be´rces, A.; Bo, C.; Boerrigter, P. M.; Cavallo, L.; Chong, D. P.; Deng, L.; Dickson, R. M.; Ellis, D. E.; Fan, L.; Fischer, T. H.; Fonseca Guerra, C.; van Gisbergen, S. J. A.; Groeneveld, J. A.; Gritsenko, O. V.; Gru¨ning, M.; Harris, F. E.; van den Hoek, P.; Jacobsen, H.; van Kessel, G.; Kootstra, F.; van Lenthe, E.; McCormack, D. A.; Osinga, V. P.; Patchkovskii, S.; Philipsen, P. H. T.; Post, D.; Pye, C. C.; Ravenek, W.; Ros, P.; Schipper, P. R. T.; Schreckenbach, G.; Snijders, J. G.; Sola, M.; Swart, M.; Swerhone, D.; te Velde, G.; Vernooijs, P.; Versluis, L.; Visser, O.; van Wezenbeek, E.; Wiesenekker, G.; Wolff, S. K.; Woo, T. K.; Ziegler, T. ADF2004.01; SCM, Theoretical Chemistry, Vrije Universiteit: Amsterdam, The Netherlands, 2004; http://www.scm.com. (19) (a) Becke, A. D. Phys. ReV. 1988, A38, 3098. (b) Perdew, J. P. Phys. ReV. 1986, B33, 8822; 1986, B34, 7406. (20) (a) van Lenthe, E.; Baerends, E.-J.; Snijders, J. J. Chem. Phys. 1993, 99, 4597. (b) van Lenthe, E.; Baerends, E.-J.; Snijders, J. J. Chem. Phys. 1996, 105, 6505. (21) (a) Klamt, A.; Schu¨u¨rmann, G. J. Chem. Soc., Perkin Trans. 1993, 2, 799. (b) Klamt, A. J. Phys. Chem. 1995, 99, 2224. (c) Klamt, A.; Jonas, V. J. Chem. Phys. 1996, 105, 9972.

3d

by full-matrix least squares using the SHELX-TL package.17 In all of the structures, there is a discrepancy between the formulas determined by elemental analysis and the formulas deduced from the crystallographic atom list because of the difficulty in locating all of the disordered water molecules and alkali counterions. Disordered water molecules and alkali counterions have been refined with partial occupancy factors and with isotropic thermal parameters. In the structures of 2a, 3a, and 2d, NH4+ and H2O could not be distinguished according to the observed electron densities; therefore, all of the positions were labeled O and assigned the oxygen atomic diffusion factor. It has been possible to distinguish the NH4+ ion only in the structures of 4a and 3d because of the presence of four H atoms located nearby the N position. Crystallographic data are given in Table 1. Selected bond distances are listed in Table 2. CIF files are given in the Supporting Information. NMR Measurements. 31P NMR spectra were recorded on a Bru¨ker AC-300 spectrometer operating at 121.5 MHz in 5-mm tubes with 1H NMR decoupling. 31P NMR chemical shifts were referenced to the usual external standard of 85% H3PO4. Elemental Analysis. Elemental analyses were performed by the Service Central d’Analyse Ele´mentaire, CNRS, 69390 Vernaison, France. IR Spectra. IR spectra were recorded on a Nicolet IRFT Magna 550 spectrophotometer using the technique of pressed KBr pellets. DFT Calculations. Calculations on [(MoV2O4)4(O3PCH2PO3)4(SO3)2]12- (2) have been carried out with the ADF program system.18 The exchange-correlation functional is the so-called Becke-Perdew/86 (BP86) functional.19 The atomic basis sets used for nonmetal atoms are triple-ζ-quality for the valence shells, supplemented with one polarization function (p type for H atoms and d type for other atoms). The valence shell of Mo (4s/4p/4d/5s) is also triple-ζ, supplemented with one p-type orbital describing the 5p shell. These basis sets have been used in conjunction with frozen cores described with one Slater orbital for each atomic shell and with the zero-order regular approximation (ZORA)20 to the relativistic effects. Basis sets of similar quality have been used to model the Na+ and NH4+ counterions in the [Na2(Mo2O4)4(O3PCH2PO3)4(SO3)2]10- and [(NH4)2(Mo2O4)4(O3PCH2PO3)4(SO3)2]10- host-guest complexes, respectively. The effect of solvation was estimated by means of the COSMO continuum model,21 using the dielectric constant of water.

C4H62ClLi9Mo6N2O62P8

Octa- and Hexanuclear Polyoxomolybdate Wheels

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5902 Inorganic Chemistry, Vol. 45, No. 15, 2006

a

1a

2a

2.568(1)-2.579(1) [2.573] 1.506(5)-1.520(4) [1.513] 1.530(4)-1.553(4) [1.542] 1.787(6)-1.814(6) [1.802]

1.530(7)-1.551(7) [1.538] 1.78(1)-1.81(1) [1.80]

1.676(4)-1.695(4) [1.686] 1.937(4)-1.965(4) [1.949] 2.053(4)-2.113(4) [2.095] 2.202(4)-2.545(4) [2.336] -

2.553(2)-2.554(2) [2.553] 1.480(8)-1.510(8) [1.494] -

1.672(8)-1.690(7) [1.683] 1.930(7)-1.957(7) [1.940] 2.066(7)-2.103(7) [2.089] 2.220(7)-2.509(8) [2.356] -

3a 1.670(12)-1.716(11) [1.690] 1.925(11)-1.951(10) [1.939] 2.096(11)-2.150(11) [2.115] 2.221(10)-2.251(11) [2.234] 1.702(10)-1.716(11) [1.709) 1.756(10)-1.777(10) [1.766] 2.127(11)-2.243(10) [2.185] 2.571(2)-2.582(2) [2.576] 1.493(12)-1.520(11) [1.504] 1.550(13), 1.551(13) 1.16, 1.15 1.505(12)-1.551(13) [1.535] 1.756(17)-1.855(16) [1.808]

4a

1.940(12)-2.002(13) [1.986]

2.563(1)-2.568(1) [2.566] 1.491(6)-1.503(5) [1.497] 1.582(6) 1.06 1.533(5)-1.549(5) [1.538] 1.785(8)-1.810(7) [1.800]

1.672(5)-1.692(5) [1.682] 1.929(5)-1.953(5) [1.939] 2.052(5)-2.109(5) [2.085] 2.260(5)-2.505(5) [2.341] -

Mo-O bond trans to the ModO bond. b Bond valence summations22 for the O atom of the P-OH bond.

Liencapsulated-O

Naencapsulated-O

P-C

P-OH bond valenceb P-OMo

PdO

MoV-MoV

MoVI-OP

MoVI-OMo

MoVIdO

MoV-Ota

MoV-OP

MoV-OMo

MoVdO

Table 2. Selected Bond Lengths (Å) for 1a-4a, 2b, 4c, 2d, and 3d 2b

1.535(5)-1.556(5) [1.544] 1.789(8)-1.802(7) [1.796] 2.360(6)-2.717(6) [2.454] -

2.555(1)-2.569(1) [2.562] 1.485(6)-1.541(5) [1.498] -

1.671(5)-1.697(5) [1.680] 1.922(5)-1.944(5) [1.936] 2.068(5)-2.110(5) [2.084] 2.266(5)-2.523(5) [2.368] -

4c

1.942(11)-2.091(12) [2.012]

2.575(1)-2.576(1) [2.575] 1.499(4)-1.511(5) [1.505] 1.595(5) 1.02 1.539(4)-1.557(4) [1.547] 1.799(6)-1.806(5) [1.805]

1.678(4)-1.700(4) [1.689] 1.945(4)-1.964(4) [1.953] 2.068(4)-2.137(4) [2.103] 2.231(4)-2.516(4) [2.367] -

2d

1.514(7)-1.544(7) [1.533] 1.772(10)- 1.794(10) [1.782] 2.302(13)- 2.605(11) [2.412] -

2.555(1)-2.566(1) [2.561 1.480(7)-1.502(7) [1.494] -

1.671(7)-1.683(7) [1.677] 1.929(6)-1.951(7) [1.938] 2.068(4)-2.137(4) [2.077] 2.235(6)-2.490(6) [2.354] -

3d

-

1.686(5)-1.704(5) [1.693] 1.936(5)-1.958(5) [1.949] 2.103(5)-2.140(5) [2.117] 2.193(5)-2.239(5) [2.212] 1.710(5)-1.711(5) [1.710) 1.758(5)-1.793(5) [1.774] 2.133(5)-2.255(5) [2.191] 2.576(1)-2.580(1) [2.578] 1.497(5)-1.529(5) [1.511] 1.559(6), 1.566(6) 1.13, 1.11 1.518(6)-1.547(5) [1.540] 1.790(7)-1.817(7) [1.805] -

Dolbecq et al.

Octa- and Hexanuclear Polyoxomolybdate Wheels

Figure 2. Synthetic routes to compounds 1-4.

Results and Discussions Synthesis. To systematically study the influence of the counterion on the nature of the MoV compounds, we have adopted the following synthetic protocol: a solution of the [Mo2O4(H2O)6]2+ cation is obtained by reduction by hydrazine of an acidic solution of the molybdate precursor, (NH4)6MoVI7O24, Na2MoVIO4, or Li2MoVIO4. After the pH is raised to 1.5 with NH3, NaOH, or LiOH, respectively, the methylenediphosphonic ligand is added. The additional template (CO32-, SO32-, MoO42-) is then added as an NH4+, Na+, or Li+ salt, and the pH rose to 5.7. The synthetic conditions used to obtain 1-4 are summarized in Figure 2. It has been possible to isolate crystals of the NH4+ salt, (NH4)12[(MoV2O4)4(O3PCH2PO3)4(CO3)2]‚24H2O (1a), analogous to the Na+ salt, Na12[(MoV2O4)4(O3PCH2PO3)4(CO3)2]‚ 72H2O (1b).13 The analogous Li+ salt (1c) has only been characterized in solution by 31P NMR. With sulfite as the template, two different octanuclear isomers have been isolated, the syn isomer (NH4)12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚26H2O (2a) with NH4+ as the counterions and the anti isomer Na12[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚39H2O (2b) with Na+ as the counterions. Despite numerous efforts, we have not been able to isolate or characterize in solution the reaction product with Li+ counterions. To study the influence of the cation on the stability of the anti isomer, 2b has been recrystallized in a solution of ammonium sulfite. A mixed NH4+ and Na+ salt Na(NH4)11[(MoV2O4)4(O3PCH2PO3)4(SO3)2]‚13H2O (2d) is isolated and, surprisingly, the X-ray structure determination (see below) has shown that the presence of one Na+ ion is sufficient to stabilize the syn isomer. When MoO42- ions are added in the synthetic medium, two different anions are isolated: a rectangular anion formed by the connection of two MoV dimers and two

MoVI octahedra by methylenediphosphonato ligands with NH4+ as the counterions, (NH4)10[(MoV2O4)2(MoVIO3)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚15H2O (3a), and the previously characterized hexanuclear wheel13 with a central {MoVIO4} tetrahedron, Na8[(MoV2O4)3(O3PCH2PO3)3(MoVIO4)]‚18H2O (3b) and Li8[(MoV2O4)3(O3PCH2PO3)3(MoVIO4)]‚19H2O (3c) with respectively Na+ and Li+ counterions. Finally a new species has been evidenced by the recrystallization of 3a in LiCl. While the first recrystallization affords a mixed NH4+ and Li+ salt, Li9(NH4)2Cl[(MoV2O4)2(MoVIO4)2(O3PCH2PO3)2(HO3PCH2PO3)2]‚22H2O (3d), of the rectangular anion, the second recrystallization has allowed isolation of a new octanuclear anion, with methylenediphosphonate ligands encapsulated within the wheel, Li12(NH4)2[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚31H2O (4a). A pure Li+ salt, Li14[(MoV2O4)4(O3PCH2PO3)4(HO3PCH2PO3)2]‚34H2O (4c), of this new anion has been synthesized in good yield by the addition of a stoichiometric amount of methylenediphosphonic acid to a solution of the oxocation obtained by reduction of lithium molybdate. All of these compounds have been studied in solution by 31P NMR spectroscopy, and the salts have been characterized in the solid state by singlecrystal X-ray diffraction, except 1c, for which it was not possible to isolate a solid, and 3c, which does not afford single crystals of sufficient quality. Crystal Structure. A common structural feature of the anions in 1-4 is the presence of {(MoV2O4)(O3PCH2PO3)} (Figure 1a) as building units, connected around the templating ligand to form cyclic compounds. The bond distances within the wheel are in the usual range (Table 2). The anions in 1a and 1b are very similar (Figure 3) and can be described as octanuclear ellipsoidal wheels built up of four MoV dimers connected by methylenediphosphonato Inorganic Chemistry, Vol. 45, No. 15, 2006

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Figure 3. (a) Ball-and-stick representation of the anion in 1a (orange sphere ) Mo, red sphere ) O, green sphere ) P, and black sphere ) C). (b) Polyhedral representation of the anion in 1b with one Na+ ion encapsulated in the wheel (orange octahedra ) MoO6, green tetrahedra ) PO3C, and blue sphere ) Na).

ligands. Two µ4-CO32- ions are encapsulated within the wheel and are located in the plane defined by the MoV ions. A µ2-O atom of the carbonate ligand ensures the connection of two dinuclear MoV units. Both anions have pseudo D2h symmetry. The only difference between 1a and 1b is that the center of the cavity of the octanuclear wheel in 1b is occupied by an octahedrally coordinated Na+ ion (Table 2) while the cavity in 1a is empty. 31P NMR experiments (see below) have shown that the same wheel is formed in solution with Li+ counterions. Therefore, the role of the Na+ ion in the formation of the octanuclear wheel in 1b is probably insignificant, and the carbonate ion plays the major role in structuring the octanuclear wheel. The inorganic skeleton of the octanuclear wheels in 2a, 2b, and 2d is similar to the one of carbonato wheels, but the templating agents inside the wheel are two pyramidal sulfite ions instead of a planar carbonate ligand (Figure 4). In 2a, the two sulfite ions are related by a mirror plane and are located on the same side of the plane defined by the eight MoV ions, while in 2b and 2d, the two S atoms of the sulfite groups are related by an inversion center and lie on two opposite sides of the molecular plane. Therefore, the anion in 2a is called the syn isomer and the anion common in 2b and 2d the anti isomer. In terms of molecular symmetry, the octanuclear wheel in 2a has Cs symmetry and that in 2b and 2d C2h symmetry. Elemental analysis has shown that 2d contains only one Na+ ion among the 12 counterions. This Na+ ion has been located by X-ray diffraction; it is disordered over two positions, related by an inversion center inside the cavity of the wheel (Figure 4b). The Na+ ion is bound to two O atoms, which ensure the connection between the methylenediphosphonato group and the MoV dimers and to one O atom of each sulfite ligand (Table 2). The coordination sphere is completed by two water molecules,

5904 Inorganic Chemistry, Vol. 45, No. 15, 2006

Figure 4. (a) Polyhedral representation of the anion in 2a showing the syn position of the sulfite groups (orange octahedra ) MoO6, green tetrahedra ) PO3C, and yellow sphere ) S). (b) Polyhedral representation of the anion common in 2b and 2d showing the anti position of the sulfite groups and the position of the Na+ ions coordinated to the two anti sulfite groups; in 2b, the two Na+ ions have full occupancy factors, while in 2d, they have half-occupancy factors. The stars refer to symmetry-equivalent positions.

one being equally disordered over two positions. In the pure Na+ salt (2b), the two positions of the Na+ cation inside the wheels have full occupancy factors. Therefore, in contrast with the carbonato wheels, the presence of the Na+ ion inside the cavity seems to have a crucial role, in the solid state, stabilizing the anti isomer. The anions in 3a and 3d have the same geometrical characteristics (Table 2). The larger sides of the rectangular ion (Figure 5a) are made of a MoV dimer, and the smaller sides of a MoVI octahedron. The corners are occupied by methylenediphosphonato ligands. This anion contains a pseudo mirror plane that intersects the two MoV dimers and thus has Cs symmetry. However, the asymmetric unit is constituted of a whole anion. There are two different kinds of methylenediphosphonato ligands: in the first one, two O atoms of each phosphonato group (labeled P1, P3, P6, and P8) are bound identically to MoV and MoVI ions, while in the second one, only one phosphonato group (P2 and P5) has two O atoms involved in the connection between a MoVI octahedron and a MoV dimer and the other phosphonato group (P4 and P7) establishes only one bond with a MoV dimer, with the other P-O bond pending. Valence bond calculations22 indicate that the O atom of this bond is protonated (Table 2). In 3d, the H atoms on the P-OH groups (H36 and H38) have been located in the Fourier difference map. They establish H bond interactions with the O atoms of the neighboring phosphate group (O28 and O9, respectively; Figure 5a). The O36-H36‚‚‚O28 interaction is stronger [H36‚‚‚O28 ) 1.66(1) Å; O36-H36‚‚‚O28 ) (22) Brese, N. E.; O’Keeffe, M. Acta Crystallogr., Sect. B 1991, 47, 192.

Octa- and Hexanuclear Polyoxomolybdate Wheels

Figure 6. (a) Mixed ball-and-stick and polyhedral representation of the anion in 4a common with the anion in 4c, with the position of the two Li+ ions encapsulated in the wheel (orange octahedra ) MoO6, red sphere ) O, green sphere ) P, black sphere ) C, and blue sphere ) Li+). (b) Polyhedral representation of the anion in 4a, with a H-bonding scheme between the O atom of the polyoxomolybdate core and the N atom of the NH4+ counterion and the protonated pending phosphonato groups (cyan sphere ) N).

Figure 5. (a) Polyhedral representation of the anion in 3a, common with the anion in 3d (orange octahedra ) MoO6 and green tetrahedra ) PO3C). The arrows indicate the possible flip-flop motion of the PO3 groups in solution. (b) Ball-and-stick representation of the anion in 3b, present also in 3c.

161.42(11)°] than the O38-H38‚‚‚O9 one [H36‚‚‚O28 ) 2.26(1) Å; O36-H36‚‚‚O28 ) 101.60(12)°]. The anion in 3b and 3c has a triangular shape (Figure 5b), with one MoV dimer at each side and one methylenediphosphonato ligand at each corner of the anion. The center of the triangle is occupied by a MoVI tetrahedron. The anion has thus C3V symmetry. In 4a and 4c, the octanuclear wheel is reminiscent of the sulfite and carbonato wheels. The difference lies in the presence of two extra methylenediphosphonato ligands, related by an inversion center, inside the cavity (Figure 6a). Thus, the anion in 4a and 4c can be compared more precisely to the anti isomer in 2b and 2d, with one phosphonato group replacing one sulfite group. The common symmetry of these two anions is C2h. Valence bond calculations (Table 2) have shown that among the three O atoms of the pending phosphate group one is protonated. In both structures, two Li+ ions occupy special positions inside the cavity of the wheels. Li1 and its symmetry-related ion are bound to four O atoms of three different methylenediphosphonato groups with a tetrahedral arrangement (Table 2 and Figure 6a). In 4a, the two NH4+ counterions are also located in the vicinity of the wheel (Figure 6b), and an intricate H-bonding scheme exists between the NH4+ cations and the O atom of the wheel [H8‚‚‚O6 ) 2.02(1) Å, N1-H8‚‚‚O6 ) 167.0(5)°; H9‚‚‚O8 ) 2.04(1) Å, N1-H9‚‚‚O8 ) 158.0(5)°; H10‚‚‚O21 )

Table 3. Computed and Observed Bond Lengths (Å, Averaged)a for syn- and anti-[(Mo2O4)4(O3PCH2PO3)4(SO3)2]12-

ModO Mo-OMo Mo-OP Mo-Ot PdO P-OMo P-C

syn (comp.)

2a (obs.)

anti (comp.)

2b (obs.)

1.736 1.971 2.112 2.30/2.52 1.525 1.576 1.826

1.686 1.949 2.095 2.336 1.513 1.542 1.802

1.736 1.970 2.114 2.31/2.50 1.525 1.576 1.826

1.680 1.936 2.084 2.368 1.498 1.544 1.796

a All computed values resulting from an optimization with the COSMO solvent model.

1.99(1) Å, N1-H10‚‚‚O21 ) 178.7(5)°; Figure 6b] and between the protonated pending phosphonato group and one O atom of the wheel [H7‚‚‚O10 ) 1.84(1) Å, O25H7‚‚‚O10 ) 163.4(5)°; Figure 6b]. DFT Calculations. Geometry optimizations carried out on the syn and anti forms of the [(MoV2O4)4(O3PCH2PO3)4(SO3)2]12- (2) anions using the continuum solvent model show that all interatomic bonding distances are correctly reproduced by calculation with a slight overestimation, comprised between 0.02 and 0.05 Å, attributable to the use of a generalized gradient approximation functional (Table 3). More importantly, all bonding distances are computed to be identical in the syn and anti conformations, indicating that the small bond-length variations observed between syn2a, on the one hand, and anti-2b and -2d, on the other hand, should be assigned to experimental uncertainties and/or to crystal forces. It also means that the energy difference computed between these two conformers should not be assigned an electronic origin but attributed either to intramolecular electrostatic or strain effects or to differences in Inorganic Chemistry, Vol. 45, No. 15, 2006

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Dolbecq et al. mol-1)

Table 4. Bond Energies (eV) and Relative Energies (kcal Calculated for the Isomers of Anion 2, Assumed (i) Isolated and (ii) Embedded in a Continuum Solvent Model (COSMO Model) and for the {X2-2} Host-Guest Complexes (X ) Na+, NH4+), in the Same Conditions bond energy (eV) 2 2 + COSMO {Na2-2} {(NH4)2-2} {Na2-2} + COSMO {(NH4)2-2} + COSMO

relative energy (kcal mol-1)

syn

anti

syn

anti

-445.3816 -592.9145 -488.4336 -528.4498 -592.1705 -633.0191

-445.4600 -592.9941 -488.5246 -528.5741 -592.1561 -632.9804

+1.81 +1.84 +2.10 +2.87 0.0 0.0

0.0 0.0 0.0 0.0 +0.33 +0.89

solvation energetics. Calculations show that 2, assumed to be isolated, is slightly more stable in the anti form, with an energy difference of 1.8 kcal mol-1. The trend and energy difference are not modified by the COSMO solvent model (Table 4). Attempts were then carried out to model the influence of the counterions by introducing into the polyoxoanion the two cations closest to the molecular cavity. All atoms in the syn and anti forms of the anionic cage were kept frozen at the position optimized for the free molecules, whereas the cations were positioned first at the places occupied by the water molecules O5W and O11W for the NH4+ salt 2a (Figure 4a) and by the Na+ ion Na3 in 2b (Figure 4b) and then allowed to move along the frozen cage. Insertion of the counterions in the isolated anionic cages does not drastically modify the relative energies of the two isomers: the computed energy difference is comprised between 2 and 3 kcal mol-1, still in favor of the anti form. Note that the Na+ counterions are slightly less favorable to the anti form than NH4+ (Table 4). Finally, embedding the host-guest complex made from the anionic cage and the two cations into the continuum solvent model reVerses the energy ordering of the two isomers: the syn form becomes slightly more stable with both types of counterions. The computed energy differences decrease below 1.0 kcal mol-1, highlighting the extreme sensitivity of the equilibrium to environmental changes. It is now found that the Na+ counterions fit somewhat better to the anti form and reduce the computed energy gap from 0.9 to 0.3 kcal mol-1 (Table 4), a trend that is in agreement with the observed conformational changes. 31P NMR Characterization of 1-4 in Aqueous Solutions. The symmetry of each anion, deduced from the crystallographic studies, and thus the number of 31P NMR expected resonances with the relative intensities are summarized in Table 5. The anion in 1a possesses a pseudo mirror plane containing the carbonato ligands; therefore, the P atoms within the same methylenediphosphonato ligand (P1 and P2, P3 and P4; Figure 3a) are expected to be equivalent and noncoupled and, therefore, P1 and P2 should give one signal and P3 and P4 should give a signal of equal intensity. The spectrum of 1a dissolved in water exhibits two resonances of equal relative intensity (Figure 7a), in agreement with these symmetry considerations. The attribution of the resonances is deduced from experiments showing the influence of the nature of the counterion on the chemical shifts of each resonance. For these experiments, 1a is dissolved in

5906 Inorganic Chemistry, Vol. 45, No. 15, 2006

Figure 7. (a) 31P NMR spectrum of 1a dissolved in water. (b) Dependence of the δ1 relative intensity vs cation concentration.

mixtures of NH4+Cl and ACl (A ) Li+, Na+, K) solutions in order to keep the ionic strength constant. When the concentration of ACl increases, the δ2 resonance is only very slightly affected, while δ1 moves continuously toward lowfield values (Figure 7b). With Na+ ions, the resonances are close to the one observed for a pure aqueous solution of 1b (Table 5). On the basis of the structural characterization of 1a, it can be expected that one alkali cation will interact directly with the anionic cavity to form an ion-pairing complex (Figure 3b). δ1 is thus attributed to the methylenediphosphonato group closest to the alkali cation, i.e., P1 and P2 phosphorus atoms. The greater sensitivity of the δ1 chemical shift toward the presence of Na+ ions shows that the anion has a greater affinity for Na+ than for K and Li+ ions and that the stability of the ion-pairing complex is increased in the order Li+ < K+ < Na+. The 31P NMR spectrum of the synthetic solution of 1c exhibits two peaks with chemical shifts intermediate between those of 1a and 1b (Table 5), showing that this compound is formed quantitatively in solution. 31P NMR spectroscopy shows that 2a and 2b decompose in a pure aqueous solution but can be stabilized by the presence of sulfite ions. The 31P NMR spectrum of a solution of 2a in ammonium sulfite (Figure 8a) exhibits two doublet of doublets corresponding to an AB system of an asymmetrical methylenediphosphonato group, in agreement with the pseudo C2h symmetry of the syn isomer. By analogy with the 31P NMR study of 1a, the four lines at 26.48, 26.35, 26.00, and 25.87 ppm are assigned to the P atoms labeled P1 and P2 in Figure 4a, which are equivalent to P5 and P6, a consequence of the presence of a pseudo mirror plane containing the two sulfite ions. Similarly, the four lines at

a

The black diamonds refer to the anti isomer (Figure 4b).

Table 5. Idealized Symmetry, Schematic Drawing of the Anions, and

31P

NMR Chemical Shifts in 1-4

Octa- and Hexanuclear Polyoxomolybdate Wheels

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Figure 8. 31P NMR spectra of a solution of (a) 2a dissolved in 0.5 M (NH4)2SO3, (* ) unknown impurities) and (b) 2b dissolved in 0.5 M Na2SO3 ([ ) anti isomer).

23.99, 23.85, 23.37, and 23.23 ppm are attributed to P3 and P4, equivalent to P7 and P8. The coupling constants 2JP-C-P between P1 and P2 (15.8 Hz) and P3 and P4 (17.0 Hz) deduced from the 31P NMR spectrum are close to those observed for other methylenediphosphonate/POM systems.12c,13 The spectrum of a solution of 2b in sodium sulfite is more complicated (Figure 8b) and can be interpreted by the presence of both the anti and syn isomers in solution. As mentioned above, the syn isomer is characterized by two doublet of doublets (peaks with no marks in Figure 8b, with one of the doublets being slightly unshielded compared to the spectrum of the syn isomer in ammonium sulfite solutions shown in Figure 8a), while the anti isomer is characterized by five resonances (peaks marked with black diamonds in Figure 8b): a single peak attributed to the four equivalent P atoms P1, P2, P1*, and P2* (Figure 4b) and a doublet of doublets (J ) 17.0 Hz) assigned to P3, P4, P3*, and P4*. The integration of the peaks allows an estimation of the proportion of each isomer: around 64% of the anti isomer and 36% of the syn isomer. To study the influence of the composition of the solution on the proportion of each isomer, 31 P NMR spectra of a solution of 2b dissolved in aqueous sodium sulfite/ammonium sulfite solutions have been recorded. Selected spectra are shown in Figure 9a. When the proportion of NH4+ cations increases, the relative intensity of the peaks attributed to the syn isomer increases continuously (Figure 9b). The proportion of the syn isomer thus reaches a value of around 70% in a pure NH4+ solution. This study shows that an equilibrium between the anti and syn forms exists in solution and that the proportion of each isomer depends on the nature of the cations (NH4+ or Na+). Contrary to what is observed in the solid state (see above), in solution the presence of Na+ ions in the medium is not a determining factor for the stabilization of the anti isomer. On the other hand, the syn isomer seems to be stable in pure NH4+ solutions. Another experimental proof of these assumptions is the fact that the 31P NMR spectrum of 2d dissolved in 0.5 M (NH4)2SO3 only exhibits the peaks of the syn isomer (Table 5). This means that the Na+ ion present in the cavity of the ring in the solid state, stabilizing the anti isomer, is replaced by NH4+ ions of the medium.

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Figure 9. (a) Changes of the 31P NMR spectrum of a solution of 2b dissolved in mixtures of 1 M Na2SO3 and 1 M (NH4)2SO3 with the proportion of NH4+ ions: (i) pure 1 M Na2SO3 aqueous solution; (ii) 1:1 1 M Na2SO3/1 M (NH4)2SO3; (iii) pure 1 M (NH4)2SO3 aqueous solution. (b) Evolution of the proportion of the syn form of the anion in 2a.

Figure 10. 31P NMR spectra of a solution of 3a dissolved in (a) H2O, (b) 6 M LiCl, (c) 1:1 6 M LiCl/6 M NaNO3, and (d) 6 M NaNO3.

The 31P NMR spectrum of a solution of 3a in a pure water solution (Figure 10a) exhibits only one doublet of doublets although two should be expected from the Cs symmetry of the anion. The presence of only one doublet indicates that the four methylenediphosphonato ligands are equivalent in solution; i.e., one doublet is attributed to P1, P2, P5, and P6 (Figure 5a) and the other one to P3, P4, P7, and P8. The shape of the doublet at high field depends on the nature of the solution; indeed, the spectrum of 3a in LiCl is similar to

Octa- and Hexanuclear Polyoxomolybdate Wheels

Figure 12. Contour plot of a two-dimensional COSY 31P NMR experiment for 4c. The mixing time was 100 ms.

Figure 11. Changes with time (a) of the 31P NMR spectrum of a solution of 3a in 3 M LiCl heated at 45 °C and (b) of the proportion of each species deduced by the integration of the peaks: (0) anion of 4a; ([) anion of 3c; (b) anion of 3a; (4) unknown species.

the spectrum of 3a in water, while a coalescence of the doublet at high field is observed in NaNO3 or NaCl solutions (Figure 10). The equivalence of P3, P4, P7, and P8 and the line broadening are characteristic of dynamic behavior and are attributed to a flip-flop motion of the four P3, P4, P7, and P8 phosphonato groups as shown by the arrows in Figure 5a. This flip-flop motion involves the breaking of one MoO(PO2C) bond and the formation of another with a concomitant move of one proton from one P-O bond to the other, probably favored by the H-bond interaction between both O atoms. The four P3, P4, P7, and P8 atoms thus become equivalent and are characterized by the doublet at high field. The presence of Na+ cations seems to facilitate this dynamic exchange. The evolution of a solution of 3a in LiCl heated at 45 °C has been followed by 31P NMR spectroscopy. A few representative spectra in the 0-116-h range are shown in Figure 11a. After 4 h, several new additional resonances are observed, attributed to three different species. The 31P NMR spectrum (Table 5) of the recrystallization product of 3a in LiCl, 4a, allows the attribution of a series of peaks (labeled with squares). The doublet of doublets marked with a black diamond is assigned to the hexanuclear anion common in 3b and 3c. The remaining doublets of doublets marked with

triangles correspond to species so far unknown in this family. This species, which contains one or more asymmetric equivalent methylenediphosphonato ligands, could be the tetranuclear complex evidenced by Chang and Zubieta14 although, as discussed in the Introduction, in this anion the connecting mode of the methylenediphosphonato ligands to the MoV dimers is different from what is observed in the complexes described here (Figure 1). While the amount of 3a decreases, the proportions of each species formed increase continuously with time (Figure 11b) in the 0-60-h range and seem to reach a plateau after 116 h. Only 20% of the anion of 3a is converted into the anion of 4a, a result consistent with the poor yield observed for the recrystallization. It should be noted that the spectrum of a solution of 3a heated at 60 °C for 116 h in pure water or in 1 M NaCl exhibits only the peaks attributed to the hexanuclear anion common in 3b and 3c and to the unknown species. The peaks of the octanuclear anion common in 4a and 4c could not be detected. Furthermore, the proportion of the initial species 3a is around 80% in pure water or a 1 M NaCl solution, while it is around 40% in 1 M LiCl. Therefore, the presence of Li+ ions in the solution seems essential for the formation of the octanuclear anion and strongly increases the degradation of 3a. The spectrum of 4c exhibits four doublets of equal intensity and a singlet at 27.10 ppm, the relative intensity of which is equal to double that of a doublet. The first components of the first AB system are at 29.68 and 29.60 ppm and the second at 20.16 and 20.08 ppm, while the lines at 24.19, 24.06, 23.32, and 23.18 ppm correspond to the second AB system. To confirm this assumption, a twodimensional COSY 31P NMR experiment was carried out (Figure 12) and clearly shows that the lines at 29.68 and 29.60 ppm and 20.16 and 20.08 ppm as well as the lines at 24.19 and 24.06 ppm and 23.32 and 23.18 ppm are respectively correlated by four off-diagonal spots. They can therefore be assigned to two different asymmetrical methylenediphosphonato ligands. The doublet at 20.16 and 20.08 ppm is attributed to the P atoms of the pending phosphonato groups (labeled P4 in Figure 6a) because these peaks are the most shielded peaks and have chemical shift values closer to uncoordinated methylenediphosphonato ligands (16.9 ppm). The other component of the AB system at 29.68 and Inorganic Chemistry, Vol. 45, No. 15, 2006

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Dolbecq et al. 29.60 ppm corresponds to the phosphonato group encapsulated within the wheel (labeled P1 in Figure 6a). The second doublet of doublets is assigned to P5 and P6, while the single peak at 27.10 ppm is attributed to P3 and P4, in comparison with the spectrum of the anti isomer in 2b. The coupling constant 2JP1-C-P4 (9.7 Hz) is smaller than the 2JP5-C-P6 constant (17.0 Hz), which is more on the order of those observed previously for ligands within the octa- and hexanuclear wheels of this family of anions (see above). In oxothiomolybdate wheels containing pyrophosphate groups, the 2JP-O-P constant has been correlated to the P-O-P angle, with larger coupling constants arising from larger P-O-P angles.23 A similar correlation does not seem possible for the methylenediphosphonato ligand. Indeed, the P1-C-P4 [118.3(3)°] and P5-C-P6 [111.6(3)°] angles determined in the structure of 4c are close and cannot explain the difference between the coupling constants. It can tentatively be supposed that in solution the P1-C-P4 angle is lowered. Conclusion In conclusion, the acid-base condensation of the [MoV2O4(H2O)6]2+ oxocation with [O3PCH2PO3]4- ligands has afforded a large diversity of compounds showing the versatility of this system. We have shown that small inorganic or organic ligands (SO32-, CO32-, O3PCH2PO34-) can be encapsulated within the octanuclear MoV framework {(MoV2O4)4(23) Cadot, E.; Pouet, M.-J.; Robert-Labarre, C.; du Peloux, C.; Marrot, J.; Se´cheresse, F. J. Am. Chem. Soc. 2004, 126, 9127.

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(O3PCH2PO3)4}. With MoO4 , two different hexanuclear anions have been isolated. It should be noted that, with CH3CO2- or HCO2- ligands, it had not been possible to characterize any product with Li+ and NH4+ counterions although double-wheel-shaped anions had been previously synthesized with Na+ counterions.13 On the contrary, with CO32-, the same octanuclear wheel is formed, whatever the counterion (NH4+, Na+, and Li+). Besides this unique case, this study has evidenced the crucial role of the counterions in the structure and stability of the MoV complexes. Such a family is of great interest for ionic conductivity measurements. Indeed, by analogy with previous results from our group on Li+ and Na+ salts of oxothiomolybdate rings,24 these salts could exhibit good ionic (protonic or alkali) conducting properties. Furthermore, the functionalization of MoV can be envisioned by the use of R-SO3-, R-PO32-, or R-AsO32- (R ) organic group) as an exogeneous ligand. 2-

Acknowledgment. A.D. thanks Jean-Daniel Compain, a student from ENS Lyon, for his contribution to the synthesis and 31P NMR study of these compounds and Marie-Jose´ Pouet and Chantal Robert-Labarre for their help concerning the NMR studies. Supporting Information Available: X-ray crystallographic data (CIF files). This material is available free of charge via the Internet at http://pubs.acs.org. IC060410+ (24) du Peloux, C.; Dolbecq, A.; Barboux, P.; Laurent, G.; Marrot, J.; Se´cheresse, F. Chem.sEur. J. 2004, 10, 3026.